Air pressure measurement based cooling

ABSTRACT

A cooling management system including component racks, a cooling system, pressure measurement devices, and a computing system within a structure. Each component rack includes an exothermic apparatus. The structure includes warm air aisle spaces and cold air aisle spaces located between the component racks. The cooling system feeds cold air into each cold air aisle space. The cold air flows through the component racks resulting in displacement of warm air from each exothermic apparatus. The warm air flows into the warm air aisle spaces and is directed back to the cooling system. The pressure measurement devices measure differential pressure values between the cold air aisle spaces and the warm air aisle spaces. The computing system monitors the differential pressure values, perform calculations associated with the differential pressure values, and control a fan speed of at least one fan within the cooling system based on the calculations.

TECHNICAL FIELD

The present invention relates to a system and associated method forusing air pressure measurements to control a cooling system.

BACKGROUND

Cooling structures typically comprises an inefficient process withlittle flexibility. Accordingly, there exists a need in the art toovercome the deficiencies and limitations described herein above.

SUMMARY

The present invention provides a system comprising: a plurality ofcomponent racks located within a structure, wherein each component rackof the plurality of component racks comprises at least one exothermicapparatus, wherein the structure comprises a plurality of warm air aislespaces and a plurality of cold air aisle spaces located between theplurality of component racks; a cooling system within the structure,wherein the cooling system is configured to feed cold air into each coldair aisle space of the plurality of cold air isle spaces, wherein thecold air flows through the component racks resulting in displacement ofwarm air from each of the at least one exothermic apparatus, and whereinthe warm air flows into the plurality of warm air aisle spaces and isdirected back to the cooling system; a plurality of pressure measurementdevices configured to measure differential pressure values between theplurality of cold air aisle spaces and the plurality of warm air aislespaces; and a computing system configured to monitor the differentialpressure values, perform calculations associated with the differentialpressure values, and control a fan speed of at least one fan within thecooling system based on the calculations.

The present invention provides a method comprising: providing a systemcomprising a plurality of component racks located within a structure, acooling system within the structure, a plurality of pressure measurementdevices within the structure, and a computing system connected to theplurality of pressure measurement devices, wherein each component rackof the plurality of component racks comprises at least one exothermicapparatus, wherein the structure comprises a plurality of warm air aislespaces and a plurality of cold air aisle spaces located between theplurality of component racks; feeding, by the cooling system, cold airinto each cold air aisle space of the plurality of cold air isle spaces,wherein the cold air flows through the component racks resulting indisplacement of warm air from each exothermic apparatus, and wherein thewarm air flows into the plurality of warm air aisle spaces and isdirected back to the cooling system; measuring, by the plurality ofpressure measurement devices, differential pressure values between theplurality of cold air aisle spaces and the plurality of warm air aislespaces; and monitoring, by the computing system, the differentialpressure values; performing, by the computing system, calculationsassociated with the differential pressure values; and controlling, bythe computing system, a fan speed of at least one fan within the coolingsystem based on the calculations.

The present invention provides a computer program product, comprising acomputer readable storage medium having a computer readable program codeembodied therein, the computer readable program code comprising analgorithm that when executed by a computer processor of a computingsystem implements a method for controlling a system comprising aplurality of component racks located within a structure, a coolingsystem within the structure, and a plurality of pressure measurementdevices within the structure, wherein each component rack of theplurality of component racks comprises at least one exothermicapparatus, and wherein the structure comprises a plurality of warm airaisle spaces and a plurality of cold air aisle spaces located betweenthe plurality of component racks, the method comprising: feeding, by thecooling system, cold air into each cold air aisle space of the pluralityof cold air isle spaces, wherein the cold air flows through thecomponent racks resulting in displacement of warm air from eachexothermic apparatus, and wherein the warm air flows into the pluralityof warm air aisle spaces and is directed back to the cooling system;measuring, by the plurality of pressure measurement devices,differential pressure values between the plurality of cold air aislespaces and the plurality of warm air aisle spaces, wherein the computingsystem is connected to the plurality of pressure measurement devicesmonitoring, by the computing system, the differential pressure values;performing, by the computing system, calculations associated with thedifferential pressure values; and controlling, by the computing system,a fan speed of at least one fan within the cooling system based on thecalculations.

The present invention advantageously provides a simple method andassociated system capable of cooling structures.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates side view of a system for managing airflow in a datacenter, in accordance with embodiments of the present invention.

FIG. 2 illustrates a perspective view of an alternative system to thesystem of FIG. 1, in accordance with embodiments of the presentinvention.

FIG. 3 illustrates an internal side view of the CRAC of FIG. 2, inaccordance with embodiments of the present invention.

FIG. 4 illustrates a top view of the system of FIG. 2, in accordancewith embodiments of the present invention.

FIG. 5 illustrates a side view of an example of an alternative system tothe system of FIG. 4, in accordance with embodiments of the presentinvention.

FIG. 6 illustrates an algorithm used by the systems of FIGS. 1-5 formanaging airflow and temperature control in a data center, in accordancewith embodiments of the present invention.

FIG. 7 illustrates a computer apparatus used for managing airflow andfire suppression control in a data center, in accordance withembodiments of the present invention.

DETAILED DESCRIPTION

FIG. 1 illustrates a perspective view of a system 5 for managing airflowin a data center 100, in accordance with embodiments of the presentinvention. Although system 5 is described with respect to datacenter 100(i.e., a room comprising multiple computers/servers storing data), notethat system 5 may be associated with respect to any type of room orbuilding comprising any type of electro/mechanical/exothermic devices.Data center 100 comprises adjacent IT equipment racks 110 (comprisingany type of electro/mechanical/exothermic devices such as, inter alia,computers, etc) located on a raised-floor 102 and placed in rows face toface or back to back in order to create alternate warm (or hot) aisles124 and cold aisles 122. Warm air flowing through data center 100 isindicated by light arrows 120 and 126 and cooled air flowing throughdata center 100 is indicated by dark arrows 114 and 116. Cold air 116directed under raised-floor 102 by a sub-floor cooling system isprovided in cold aisles 122 in between adjacent rack rows facing eachother through perforated floor tiles 118 (i.e., comprising an airflowregister that includes a device for modifying or restricting an airflowof cold air 116) and is directed through a front of each of equipmentracks 110. The cold air is collected by cooling fans of theelectro/mechanical/exothermic devices in the equipment racks 110 and isexhausted (as warm air 120) at a backside of a rack row in warm aisles124 where two adjacent rack rows are located back to back. The exhaustedwarm air 126 is collected in computer room air conditioning units (CRAC)306 for cooling and is circulated back as cold air 114 to the sub-floorcooling system.

FIG. 2 illustrates a perspective view of an alternative system 5 a tosystem 5 of FIG. 1, in accordance with embodiments of the presentinvention. System 5 a comprises a data center 300 comprising adjacent ITequipment racks 110 (comprising any type ofelectro/mechanical/exothermic devices such as, inter alia, computers,etc) located on a raised-floor 102 and placed in rows face to face orback to back in order to create alternate warm aisles 124 and coldaisles 122 as described, supra, with respect to FIG. 1. Warm air flowthrough data center 300 is indicated by light arrows and cold air flowthrough data center 300 is indicated by dark arrows. System 5 a allowsfor separation of warm air from cold air by having the warm air beingprevented from re-circulating into the cold aisles 122 by using a roofarrangement 302 to isolate the cold aisles 122 from the warm aisles 124.The roof arrangement 302 is disposed over the cold aisles 122. The roofarrangement 302 creates cold air tunnels thereby avoiding warm spots andallowing for maintaining a homogeneous air environment along the coldaisle tunnels. With this arrangement, all cold air produced within thecold aisles goes through the electro/mechanical/exothermic devices andthere is no loss of cold air. The roof arrangement 302 may vary in sizeand material used. In a preferred embodiment, the roof is made of aplastic film extending from one row to an opposite row and coveringwhole cold aisle 122. The segregation of warm/cold air may be achievedby using different devices such as aluminum structures supportingplastic roofs and side curtains (adjusted to a size of the IT equipmentracks 110) and end curtains to close a corridor. The tunnels createdallow for maintaining (within the tunnels area) uniform temperature andrelative humidity air values. The warm air 310 exhausted from severalwarm aisles is directed towards the ceiling by an air mixing unit 304.The air mixing unit 304 is preferably located close to the ceiling ofthe data center 300. The air mixing unit 304 delivers air 314(comprising a mixture of outside air 312 and the warm air input 310 fromthe data center room) to a computer room air conditioning unit (CRAC)306 and/or chilled water apparatus 308 (i.e., for providing chilledwater for cooling) for cooling thereby generating a cooled air flow 316for data center 300 cooling. The CRAC 306 (as further described withrespect to FIG. 3) may be coupled to a chilled water apparatus 308 andprovides cooled air flow 316 that falls within the temperature andrelative humidity values required by the electro/mechanical/exothermicdevice specifications. The cooled air flow 316 is finally pushed intothe sub-floor 102 and blown into the cold aisles 122 through theperforated tiles as previously described. Pressure sensors 400 a . . .400 n and a control computing system (as further described with respectto FIGS. 4 and 5) are coupled to the CRAC 306 to measure and uniformlycontrol respectively a volume of cold air 316 and/or chilled water(i.e., from chilled water apparatus 308) necessary to meet requiredtemperature and relative humidity values. Differential pressure readingsfrom the pressure sensors 400 a . . . 400 n are used to drive a speed ofa fan within the CRAC 306 accordingly to create a uniform pressurewithin each of cold air aisles 122.

FIG. 3 illustrates an internal side view of CRAC 306 of FIG. 2, inaccordance with embodiments of the present invention. CRAC 306 isconfigured (in combination with chilled water apparatus 308) to retrieveair 314 and generate cold air 316. The cold air 316 is directed out ofthe CRAC 306 and into the raised-floor 102 using an internal fan 504. Aspeed of the fan is controlled by differential pressure readings fromthe pressure sensors 400 a . . . 400 n.

FIG. 4 illustrates a top view of an example of an alternative system 5 bto systems 5 and 5 a of FIGS. 1 and 2, in accordance with embodiments ofthe present invention. System allows for:

1. Measurement of a differential pressure in each of cold aisles 122.

2. Controlling a fan speed (in each of CRACs/recyclers 306 a . . . 306n) to ensure a minimum positive pressure in a cold aisle having a lowestpressure.

3. Adjusting an aisle pressure balance manually or automatically.

4. Detecting and alerting a confinement failure (i.e., air volumeincrease and pressure decrease).

The computer room in system 5 b may be cooled via CRACs/recyclers 306 a. . . 306 n that cool warm air by directing the warm air through heatexchangers/AC units. After passing through the heat exchangers/AC units,the air may be pass fed with cold water. A temperature of outgoing airfrom the heat exchangers/AC units may be maintained at a constant levelby electrically varying a quantity of water which crosses water drumsused to cool the air.

System 5 b comprises CRACs/recyclers 306 a . . . 306 n, associated coldaisles 122 and warm aisles 124, pressure sensors 400 a . . . 400 n, anda controller computer 405. Each of cold aisles 122 comprises anassociated pressure sensor of pressure sensors 400 a . . . 400 n. Notethat the controller computer 405 may be used in any of FIGS. 1-7 formanaging airflow (and any other described systems and attributes) in adata center. The pressure sensors 400 a . . . 400 n generate adifferential pressure reading (Pa-P1 . . . Pa-P4) between airflow in thecold aisles 122 (P1 . . . P4) and an ambient pressure (Pa) in thecomputer room. The differential pressure readings (Pa-P1 . . . Pa-P4)are monitored by the controller computer 405 in order to performcalculations (associated with the differential pressure values) andcontrol a fan speed of at least one fan within CRACs/recyclers 306 a . .. 306 n based on the calculations. Results of the calculations maydetermine that a first differential pressure value (associated with oneof the cold aisles 122) comprises a lowest pressure value as compared toall other pressure values. In this case the controller computer 405 may:

1. Adjust a fan speed of an associated CRAC/recycler (of CRACs/recyclers306 a . . . 306 n) such that the associated cold air aisle spacecomprises a minimum positive differential pressure value.

2. Adjust an airflow register modifying airflow in the associated coldair aisle space such that the associated cold air aisle space comprisesa minimum positive differential pressure value.

Alternatively or additionally the CRAC/recycler(s) 306 a . . . 306 n mayeach include a water recycler associated a cold air aisle space and thedifferential pressure readings (Pa-P1 . . . Pa-P4) are monitored by thecontroller computer 405 in order to perform calculations (associatedwith the differential pressure values). Each of the water recyclerscomprises a temperature sensor and a water output valve. The temperaturesensor is configured to monitor a temperature of an air output for anassociated water recycler. The controller computer 405 monitors aconsumption of cold water for each water recycler and a temperature foreach air output. The calculations are further associated the consumptionof cold water for each water recycler and each monitored temperature.Based on the calculations, the controller computer 405 may control eachwater output valve to control water flow from each of the waterrecyclers based on the monitored temperatures. Each of the waterrecyclers may additionally include humidity measurement devices andsteam generators associated with cold air aisle spaces 122 and thecontroller computer 405 may be configured to control output from eachsteam generator based on humidity measurements from the humiditymeasurement devices in order to keep a humidity level constant in eachof cold air aisle spaces 122.

FIG. 5 illustrates a side view of an example of an alternative system 5c to system 5 b of FIG. 4, in accordance with embodiments of the presentinvention. In contrast to system 5 b of FIG. 4, system 5 c comprises asingle CRAC/recycler 306 and the pressure sensors 400 a . . . 400 n aremounted in a roof arrangement 302 for each of the cold aisles 122.

FIG. 6 illustrates an algorithm used by the systems 5 of FIGS. 1-5 formanaging airflow in a data center, in accordance with embodiments of thepresent invention. In step 602, a cooling system feeds cold air intocold air isle spaces of a data center that includes component racks(each including at least one exothermic apparatus). The cold air flowsthrough the component racks resulting in displacement of warm air fromeach exothermic apparatus. The warm air flows into warm air aisle spacesand is directed back to the cooling system. In step 604, a plurality ofpressure measurement devices (e.g., pressure transducers) measuredifferential pressure values between the cold air aisle spaces and thewarm air aisle spaces. In response, a computing system monitors thedifferential pressure values. In optional step 608, the cooling systemcomprises a plurality of water recyclers (each including a temperaturesensor and a water output valve) associated with the cold air aislespaces and each temperature sensor monitors a temperature of an airoutput for an associated water recycler. In optional step 612, thecomputing system monitors a consumption of cold water for each of thewater recyclers and a temperature for each of the air outputs. Inoptional step 618, the cooling system comprises humidity measurementdevices and steam generators associated with the cold air aisle spacesand the humidity measurement devices generate humidity measurements formonitoring by the computing system. In step 624, the computing systemperforms calculations associated with the differential pressure values(from step 604), the temperature measurements (from step 608), the waterconsumption (from step 612), and the humidity measurements (from step618). In step 628, the computing system controls a fan speed of at leastone fan within the cooling system based on results of the saidcalculations. For example, the calculations may determine that a firstdifferential pressure value (associated with a first cold air aislespace) comprises a lowest pressure value (as compared to all otherpressure values) and in response the fan speed of the at least one fanis adjusted such that the first cold air aisle space comprises a minimumpositive differential pressure value. The computing system mayadditionally or alternatively control an airflow register allowing formodification of an airflow the first cold air aisle space such the firstcold air aisle space comprises a minimum positive differential pressurevalue. In step 630, the computing system may control each water outputvalve to control water flow from each water recycler based on each ofthe temperature measurements (from step 608). In step 632, the computingsystem controls output from each steam generator based on the humiditymeasurements from said humidity measurement devices (from step 618) inorder to keep a humidity level constant in each of the cold air aislespaces and step 604 is repeated.

FIG. 7 illustrates a computer apparatus 90 (e.g., controller computer405 in FIG. 4) used for managing airflow (or other systems) in a datacenter, in accordance with embodiments of the present invention. Thecomputer system 90 comprises a processor 91, an input device 92 coupledto the processor 91, an output device 93 coupled to the processor 91,and memory devices 94 and 95 each coupled to the processor 91. The inputdevice 92 may be, inter alia, a keyboard, a software application, amouse, etc. The output device 93 may be, inter alia, a printer, aplotter, a computer screen, a magnetic tape, a removable hard disk, afloppy disk, a software application, etc. The memory devices 94 and 95may be, inter alia, a hard disk, a floppy disk, a magnetic tape, anoptical storage such as a compact disc (CD) or a digital video disc(DVD), a dynamic random access memory (DRAM), a read-only memory (ROM),etc. The memory device 95 includes a computer code 97. The computer code97 includes algorithms (e.g., the algorithm of FIG. 6) for managingairflow (or other systems) in a data center. The processor 91 executesthe computer code 97. The memory device 94 includes input data 96. Theinput data 96 includes input required by the computer code 97. Theoutput device 93 displays output from the computer code 97. Either orboth memory devices 94 and 95 (or one or more additional memory devicesnot shown in FIG. 7) may comprise the algorithm of FIG. 6 and may beused as a computer usable medium (or a computer readable medium or aprogram storage device) having a computer readable program code embodiedtherein and/or having other data stored therein, wherein the computerreadable program code comprises the computer code 97. Generally, acomputer program product (or, alternatively, an article of manufacture)of the computer system 90 may comprise the computer usable medium (orsaid program storage device).

Still yet, any of the components of the present invention could becreated, integrated, hosted, maintained, deployed, managed, serviced,etc. by a service provider who offers to for manage airflow (or othersystems) in a data center. Thus the present invention discloses aprocess for deploying, creating, integrating, hosting, maintaining,and/or integrating computing infrastructure, comprising integratingcomputer-readable code into the computer system 90, wherein the code incombination with the computer system 90 is capable of performing amethod for managing airflow (or other systems) in a data center. Inanother embodiment, the invention provides a method that performs theprocess steps of the invention on a subscription, advertising, and/orfee basis. That is, a service provider, such as a Solution Integrator,could offer to manage airflow (or other systems) in a data center. Inthis case, the service provider can create, maintain, support, etc. acomputer infrastructure that performs the process steps of the inventionfor one or more customers. In return, the service provider can receivepayment from the customer(s) under a subscription and/or fee agreementand/or the service provider can receive payment from the sale ofadvertising content to one or more third parties.

While FIG. 7 shows the computer system 90 as a particular configurationof hardware and software, any configuration of hardware and software, aswould be known to a person of ordinary skill in the art, may be utilizedfor the purposes stated supra in conjunction with the particularcomputer system 90 of FIG. 7. For example, the memory devices 94 and 95may be portions of a single memory device rather than separate memorydevices.

While embodiments of the present invention have been described hereinfor purposes of illustration, many modifications and changes will becomeapparent to those skilled in the art. Accordingly, the appended claimsare intended to encompass all such modifications and changes as fallwithin the true spirit and scope of this invention.

The invention claimed is:
 1. A system comprising: a plurality ofcomponent racks located within a structure, wherein each component rackof said plurality of component racks comprises at least one exothermicapparatus, wherein said structure comprises a plurality of warm airaisle spaces and a plurality of cold air aisle spaces located betweensaid plurality of component racks; a cooling system within saidstructure, wherein said cooling system is configured to feed cold airinto each cold air aisle space of said plurality of cold air islespaces, wherein said cold air flows through said component racksresulting in displacement of warm air from each said at least oneexothermic apparatus, and wherein said warm air flows into saidplurality of warm air aisle spaces and is directed back to said coolingsystem; a plurality of pressure measurement devices configured tomeasure differential pressure values between said plurality of cold airaisle spaces and said plurality of warm air aisle spaces; a computingsystem configured to monitor said differential pressure values, performcalculations associated with said differential pressure values, andcontrol a fan speed of at least one fan within said cooling system basedon said calculations; and an alarm system configured to notify a user ifany of said pressure values exceeds a predetermined threshold.
 2. Thesystem of claim 1, wherein said calculations determine that a firstdifferential pressure value of said differential pressure valuescomprises a lowest pressure value as compared to all other pressurevalues of said differential pressure values, wherein said firstdifferential pressure value is associated with a first cold air aislespace of said plurality of cold air isle spaces, and wherein saidcomputing system is configured to adjust the fan speed of said at leastone fan such that said first cold air aisle space comprises a minimumpositive differential pressure value.
 3. The system of claim 1, whereinsaid calculations determine that a first differential pressure value ofsaid differential pressure values comprises a lowest differentialpressure value as compared to all other differential pressure values ofsaid differential pressure values, wherein said calculations furtherdetermine that a last differential pressure value of said differentialpressure values comprises a highest differential pressure value ascompared to all other differential pressure values of said differentialpressure values, wherein said first differential pressure value isassociated with a first cold air aisle space of said plurality of coldair isle spaces, wherein said last differential pressure value isassociated with last cold air aisle space of said plurality of cold airisle spaces, and wherein said computing system is configured to adjustan airflow register modifying an airflow in said first cold air aislespace and said last cold air aisle space such that said first cold airaisle space and said last cold air aisle space each comprise a minimumdifference of a positive differential pressure value.
 4. The system ofclaim 1, wherein said cooling system comprises a plurality of waterrecyclers, wherein each water recycler of said plurality of waterrecyclers is associated with a different cold air aisle space of saidplurality of cold air aisle spaces, wherein each said water recyclercomprises a temperature sensor and a water output valve, wherein eachsaid temperature sensor is configured to monitor a temperature of eachan air output for an associated water recycler of said plurality ofwater recyclers, wherein said computing system is further configured tomonitor a consumption of cold water for each said water recycler and atemperature for each said air output, and wherein said calculations arefurther associated with said consumption of cold water for each saidwater recycler and each said temperature.
 5. The system of claim 4,wherein said computing system is further configured to control each saidwater output valve to control water flow from each said water recyclerbased on each said temperature.
 6. The system of claim 4, wherein saidcooling system further comprises humidity measurement devices and steamgenerators associated with said plurality of cold air aisle spaces, andwherein said computing system is further configured to control outputfrom each steam generator of said steam generators based on humiditymeasurements from said humidity measurement devices in order to keep ahumidity level constant in each of said plurality of cold air aislespaces.
 7. The system of claim 1, wherein said cooling system comprisesa plurality of cooling devices, wherein each cooling device of saidplurality of cooling devices is associated with a different cold airaisle space of said plurality of cold air aisle spaces, wherein eachsaid cooling device comprises a fan, and wherein said computing systemis configured to control a fan speed of each said fan based on saidcalculations.
 8. The system of claim 7, wherein said calculationsdetermine that a first differential pressure value of said differentialpressure values comprises a lowest differential pressure value ascompared to all other differential pressure values of said differentialpressure values, wherein said first differential pressure value isassociated with a first cold air aisle space of said plurality of coldair isle spaces, and wherein said computing system is configured toadjust a first fan speed of a first fan within a first cooling device ofsaid plurality of cooling devices, wherein said first cooling device isassociated with said first cold air aisle space, and wherein said firstfan speed is adjusted such that said first cold air aisle spacecomprises a minimum positive differential pressure value.
 9. The systemof claim 8, wherein each said fan comprises a same fan speed.
 10. Thesystem of claim 1, wherein said calculations are used to determine coldair leakage values associated with an amount of cold air leakage in coldair isle space of said plurality of cold air isle spaces.
 11. The systemof claim 1, wherein said at least one exothermic apparatus comprises anelectrical apparatus.
 12. A method comprising: providing a systemcomprising a plurality of component racks located within a structure, acooling system within said structure, a plurality of pressuremeasurement devices within said structure, an alarm system, and acomputing system connected to said plurality of pressure measurementdevices, wherein each component rack of said plurality of componentracks comprises at least one exothermic apparatus, wherein saidstructure comprises a plurality of warm air aisle spaces and a pluralityof cold air aisle spaces located between said plurality of componentracks; feeding, by said cooling system, cold air into each cold airaisle space of said plurality of cold air isle spaces, wherein said coldair flows through said component racks resulting in displacement of warmair from each said at least one exothermic apparatus, and wherein saidwarm air flows into said plurality of warm air aisle spaces and isdirected back to said cooling system; measuring, by said plurality ofpressure measurement devices, differential pressure values between saidplurality of cold air aisle spaces and said plurality of warm air aislespaces; monitoring, by said computing system, said differential pressurevalues; performing, by said computing system, calculations associatedwith said differential pressure values; controlling, by said computingsystem, a fan speed of at least one fan within said cooling system basedon said calculations; and notifying, by said computing system executingsaid alarm system, a user if any of said pressure values exceeds apredetermined threshold.
 13. The method of claim 12, wherein saidcalculations determine that a first differential pressure value of saiddifferential pressure values comprises a lowest pressure value ascompared to all other pressure values of said differential pressurevalues, wherein said first differential pressure value is associatedwith a first cold air aisle space of said plurality of cold air islespaces, and wherein said method further comprises: adjusting, by saidcomputing system, the fan speed of said at least one fan such that saidfirst cold air aisle space comprises a minimum positive differentialpressure value.
 14. The method of claim 12, wherein said calculationsdetermine that a first differential pressure value of said differentialpressure values comprises a lowest differential pressure value ascompared to all other differential pressure values of said differentialpressure values, wherein said calculations further determine that a lastdifferential pressure value of said differential pressure valuescomprises a highest differential pressure value as compared to all otherdifferential pressure values of said differential pressure values,wherein said first differential pressure value is associated with afirst cold air aisle space of said plurality of cold air isle spaces,wherein said last differential pressure value is associated with lastcold air aisle space of said plurality of cold air isle spaces, andwherein said method further comprises: adjusting by said computingsystem, an airflow register allowing for a modification of an airflow insaid first cold air aisle space and said last cold air aisle space suchthat said first cold air aisle space and said last cold air aisle spaceeach comprise a minimum difference of a positive differential pressurevalue.
 15. The method of claim 12, wherein said cooling system comprisesa plurality of water recyclers, wherein each water recycler of saidplurality of water recyclers is associated with a different cold airaisle space of said plurality of cold air aisle spaces, wherein eachsaid water recycler comprises a temperature sensor and a water outputvalve, and wherein said method further comprises: monitoring, by eachsaid temperature sensor, a temperature of each an air output for anassociated water recycler of said plurality of water recyclers; andmonitoring, by said computing system, a consumption of cold water foreach said water recycler and a temperature for each said air output,wherein said calculations are further associated with said consumptionof cold water for each said water recycler and each said temperature.16. The method of claim 15, further comprising: controlling, by saidcomputing system, each said water output valve to control water flowfrom each said water recycler based on each said temperature.
 17. Themethod of claim 15, wherein said cooling system further compriseshumidity measurement devices and steam generators associated with saidplurality of cold air aisle spaces, and wherein said method furthercomprises: controlling, by said computing system, an output from eachsteam generator of said steam generators based on humidity measurementsfrom said humidity measurement devices in order to keep a humidity levelconstant in each of said plurality of cold air aisle spaces.
 18. Themethod of claim 12, wherein said cooling system comprises a plurality ofcooling devices, wherein each cooling device of said plurality ofcooling devices is associated with a different cold air aisle space ofsaid plurality of cold air aisle spaces, wherein each said coolingdevice comprises a fan, and wherein said method further comprises:controlling, by said computing system, a fan speed of each said fanbased on said calculations.
 19. The method of claim 12, wherein saidcalculations determine that a first differential pressure value of saiddifferential pressure values comprises a lowest differential pressurevalue as compared to all other differential pressure values of saiddifferential pressure values, wherein said first differential pressurevalue is associated with a first cold air aisle space of said pluralityof cold air isle spaces, and wherein said method further comprises:adjusting, by said computing system, a first fan speed of a first fanwithin a first cooling device of said plurality of cooling devices,wherein said first cooling device is associated with said first cold airaisle space, and wherein said first fan speed is adjusted such that saidfirst cold air aisle space comprises a minimum positive differentialpressure value.
 20. The method of claim 18, wherein each said fancomprises a same fan speed.
 21. The method of claim 12, wherein saidcalculations are used to determine cold air leakage values associatedwith an amount of cold air leakage in cold air isle space of saidplurality of cold air isle spaces.
 22. The method of claim 12, furthercomprising: providing a process for supporting computer infrastructure,said process comprising providing at least one support service for atleast one of creating, integrating, hosting, maintaining, and deployingcomputer-readable code in the computing system, wherein the code incombination with the computing system is capable of performing themethod of claim
 12. 23. A computer program product, comprising acomputer readable hardware storage device storing a computer readableprogram code, the computer readable program code comprising an algorithmthat when executed by a computer processor of a computing systemimplements a method for controlling a system comprising a plurality ofcomponent racks located within a structure, a cooling system within saidstructure, an alarm system, and a plurality of pressure measurementdevices within said structure, wherein each component rack of saidplurality of component racks comprises at least one exothermicapparatus, and wherein said structure comprises a plurality of warm airaisle spaces and a plurality of cold air aisle spaces located betweensaid plurality of component racks, said method comprising: feeding, bysaid cooling system, cold air into each cold air aisle space of saidplurality of cold air isle spaces, wherein said cold air flows throughsaid component racks resulting in displacement of warm air from eachsaid at least one exothermic apparatus, and wherein said warm air flowsinto said plurality of warm air aisle spaces and is directed back tosaid cooling system; measuring, by said plurality of pressuremeasurement devices, differential pressure values between said pluralityof cold air aisle spaces and said plurality of warm air aisle spaces,wherein said computing system is connected to said plurality of pressuremeasurement devices; monitoring, by said computing system, saiddifferential pressure values; performing, by said computing system,calculations associated with said differential pressure values;controlling, by said computing system, a fan speed of at least one fanwithin said cooling system based on said calculations; and notifying, bysaid computing system executing said alarm system, a user if any of saidpressure values exceeds a predetermined threshold.